# Monte Carlo vs Temporal Difference Learning [[mc-vs-td]]

The last thing we need to discuss before diving into Q-Learning is the two learning strategies.

Remember that an RL agent **learns by interacting with its environment.** The idea is that **given the experience and the received reward, the agent will update its value function or policy.**

Monte Carlo and Temporal Difference Learning are two different **strategies on how to train our value function or our policy function.** Both of them **use experience to solve the RL problem.**

On one hand, Monte Carlo uses **an entire episode of experience before learning.** On the other hand, Temporal Difference uses **only a step ( \\(S_t, A_t, R_{t+1}, S_{t+1}\\) ) to learn.**

We'll explain both of them **using a value-based method example.**

## Monte Carlo: learning at the end of the episode [[monte-carlo]]

Monte Carlo waits until the end of the episode, calculates  \\(G_t\\) (return) and uses it as **a target for updating  \\(V(S_t)\\).**

So it requires a **complete episode of interaction before updating our value function.**

  <img src="https://huggingface.co/datasets/huggingface-deep-rl-course/course-images/resolve/main/en/unit3/monte-carlo-approach.jpg" alt="Monte Carlo"/>


If we take an example:

  <img src="https://huggingface.co/datasets/huggingface-deep-rl-course/course-images/resolve/main/en/unit3/MC-2.jpg" alt="Monte Carlo"/>


- We always start the episode **at the same starting point.**
- **The agent takes actions using the policy**. For instance, using an Epsilon Greedy Strategy, a policy that alternates between exploration (random actions) and exploitation.
- We get **the reward and the next state.**
- We terminate the episode if the cat eats the mouse or if the mouse moves > 10 steps.

- At the end of the episode, **we have a list of State, Actions, Rewards, and Next States tuples**
For instance [[State tile 3 bottom, Go Left, +1, State tile 2 bottom], [State tile 2 bottom, Go Left, +0, State tile 1 bottom]...]

- **The agent will sum the total rewards \\(G_t\\)** (to see how well it did).
- It will then **update \\(V(s_t)\\) based on the formula**

  <img src="https://huggingface.co/datasets/huggingface-deep-rl-course/course-images/resolve/main/en/unit3/MC-3.jpg" alt="Monte Carlo"/>

- Then **start a new game with this new knowledge**

By running more and more episodes, **the agent will learn to play better and better.**

  <img src="https://huggingface.co/datasets/huggingface-deep-rl-course/course-images/resolve/main/en/unit3/MC-3p.jpg" alt="Monte Carlo"/>

For instance, if we train a state-value function using Monte Carlo:

- We initialize our value function **so that it returns 0 value for each state**
- Our learning rate (lr) is 0.1 and our discount rate is 1 (= no discount)
- Our mouse **explores the environment and takes random actions**

  <img src="https://huggingface.co/datasets/huggingface-deep-rl-course/course-images/resolve/main/en/unit3/MC-4.jpg" alt="Monte Carlo"/>


- The mouse made more than 10 steps, so the episode ends .

  <img src="https://huggingface.co/datasets/huggingface-deep-rl-course/course-images/resolve/main/en/unit3/MC-4p.jpg" alt="Monte Carlo"/>



- We have a list of state, action, rewards, next_state, **we need to calculate the return \\(G{t=0}\\)**

\\(G_t = R_{t+1} + R_{t+2} + R_{t+3} ...\\) (for simplicity, we don't discount the rewards)

\\(G_0 = R_{1} + R_{2} + R_{3}…\\)

\\(G_0 = 1 + 0 + 0 + 0 + 0 + 0 + 1 + 1 + 0 + 0\\)

\\(G_0 = 3\\)

- We can now compute the **new** \\(V(S_0)\\):

  <img src="https://huggingface.co/datasets/huggingface-deep-rl-course/course-images/resolve/main/en/unit3/MC-5.jpg" alt="Monte Carlo"/>

\\(V(S_0) = V(S_0) + lr * [G_0 — V(S_0)]\\)

\\(V(S_0) = 0 + 0.1 * [3 – 0]\\)

\\(V(S_0) = 0.3\\)


  <img src="https://huggingface.co/datasets/huggingface-deep-rl-course/course-images/resolve/main/en/unit3/MC-5p.jpg" alt="Monte Carlo"/>


## Temporal Difference Learning: learning at each step [[td-learning]]

**Temporal Difference, on the other hand, waits for only one interaction (one step) \\(S_{t+1}\\)** to form a TD target and update \\(V(S_t)\\) using \\(R_{t+1}\\) and \\( \gamma * V(S_{t+1})\\).

The idea with **TD is to update the \\(V(S_t)\\) at each step.**

But because we didn't experience an entire episode, we don't have \\(G_t\\) (expected return). Instead, **we estimate \\(G_t\\) by adding \\(R_{t+1}\\) and the discounted value of the next state.**

This is called bootstrapping. It's called this **because TD bases its update in part on an existing estimate \\(V(S_{t+1})\\) and not a complete sample \\(G_t\\).**

  <img src="https://huggingface.co/datasets/huggingface-deep-rl-course/course-images/resolve/main/en/unit3/TD-1.jpg" alt="Temporal Difference"/>


This method is called TD(0) or **one-step TD (update the value function after any individual step).**

  <img src="https://huggingface.co/datasets/huggingface-deep-rl-course/course-images/resolve/main/en/unit3/TD-1p.jpg" alt="Temporal Difference"/>

If we take the same example,

  <img src="https://huggingface.co/datasets/huggingface-deep-rl-course/course-images/resolve/main/en/unit3/TD-2.jpg" alt="Temporal Difference"/>

- We initialize our value function so that it returns 0 value for each state.
- Our learning rate (lr) is 0.1, and our discount rate is 1 (no discount).
- Our mouse begins to explore the environment and takes a random action: **going to the left**
- It gets a reward  \\(R_{t+1} = 1\\) since **it eats a piece of cheese**

  <img src="https://huggingface.co/datasets/huggingface-deep-rl-course/course-images/resolve/main/en/unit3/TD-2p.jpg" alt="Temporal Difference"/>


  <img src="https://huggingface.co/datasets/huggingface-deep-rl-course/course-images/resolve/main/en/unit3/TD-3.jpg" alt="Temporal Difference"/>

We can now update  \\(V(S_0)\\):

New  \\(V(S_0) = V(S_0) + lr * [R_1 + \gamma * V(S_1) - V(S_0)]\\)

New \\(V(S_0) = 0 + 0.1 * [1 + 1 * 0–0]\\)

New \\(V(S_0) = 0.1\\)

So we just updated our value function for State 0.

Now we **continue to interact with this environment with our updated value function.**

  <img src="https://huggingface.co/datasets/huggingface-deep-rl-course/course-images/resolve/main/en/unit3/TD-3p.jpg" alt="Temporal Difference"/>

  To summarize:

  - With *Monte Carlo*, we update the value function from a complete episode, and so we **use the actual accurate discounted return of this episode.**
  - With *TD Learning*, we update the value function from a step, and we replace \\(G_t\\), which we don't know, with **an estimated return called the TD target.**

  <img src="https://huggingface.co/datasets/huggingface-deep-rl-course/course-images/resolve/main/en/unit3/Summary.jpg" alt="Summary"/>
